The application status and development of laser shock processing

Wu Jiajun; Zhao Jibin; Qiao Hongchao; Lu Ying; Sun Boyu; Hu Taiyou; Zhang Yinuo

doi:10.12086/oee.2018.170690

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Wu Jiajun, Zhao Jibin, Qiao Hongchao, et al. The application status and development of laser shock processing[J]. Opto-Electronic Engineering, 2018, 45(2): 170690. doi: 10.12086/oee.2018.170690

Citation:

Wu Jiajun, Zhao Jibin, Qiao Hongchao, et al. The application status and development of laser shock processing[J]. Opto-Electronic Engineering, 2018, 45(2): 170690. doi: 10.12086/oee.2018.170690

The application status and development of laser shock processing

1.
Manufacturing Technology Department, Shenyang Institute of Automation, Chinese Academy of Sciences, Shenyang, Liaoning 110016, China
2.
School of Engineering Sciences, University of Chinese Academy of Sciences, Beijing 100049, China

Fund Project: Supported by National Natural Science Foundation of China (51501219), National Key Development Program (2016YFB1102704), NSFC-Liaoning Province United Foundation (U1608259) and National Natural Science Foundation of Liaoning Province (2015020115)

More Information

Corresponding author: Zhao Jibin, E-mail: jbzhao@sia.cn

Received Date 15 December 2017

Revised Date 20 January 2018

Published Date 22 February 2018

Abstract

Abstract

Laser shock processing is a new type of surface modification technology that can improve the fatigue life of materials by using laser-induced plasma shock waves. It has the advantages of significant strengthening effect, strong controllability and good adaptability. Laser shock processing plays an important role in improving the structural reliability, the fatigue strength of parts and the service life of materials. In recent years, the technology has received widespread attention and developed rapidly. This paper briefly introduces the basic principle, characteristics and application fields of laser shock processing, and summarizes the development and research results of laser shock processing. In view of the current situation of laser shock processing at home and abroad, some problems of the technology that need to be solved now are put forward. Finally, the application prospect of laser shock processing is forecasted.
- laser shock processing /
- plasma /
- shock waves /
- fatigue life /
- surface strengthen

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References

[1]	Alexander W O, Davies G J, Reynolds K A, et al. Essential Metallurgy for Engineers[M]. United Kingdom: Van Nostrand Reinhold, 1985. Google Scholar
[2]	曼森S S. 金属疲劳损伤: 机理、探测、预防和维修[M]. 陆索, 译. 北京: 国防工业出版社, 1976. Google Scholar Manson S S. Metal Fatigue Damage[M]. Lu S, trans. Beijing: National Defense Industry Press, 1976. Google Scholar
[3]	徐滨士, 马世宁, 刘世参, 等.纳米表面工程[M].北京:中国化工出版社, 2000. Google Scholar Xu B S, Ma S N, Liu S C, et al. Nano Surface Engineering[M]. Beijing: Chemical Industry Press, 2000. Google Scholar
[4]	李松夏, 乔红超, 赵吉宾, 等.激光冲击强化技术原理及研究发展[J].光电工程, 2017, 44(6): 569-576. Google Scholar Li S X, Qiao H C, Zhao J B, et al. Research and development of laser shock processing technology[J]. Opto-Electronic Engineering, 2017, 44(6): 569-576. Google Scholar
[5]	Singh G, Grandhi R V, Stargel D S. Modeling and parameter design of a laser shock peening process[J]. International Journal for Computational Methods in Engineering Science and Mechanics, 2011, 12(5): 233-253. doi: 10.1080/15502287.2010.542795 CrossRef Google Scholar
[6]	李应红.激光冲击强化理论与技术[M].北京:科学出版社, 2013. Google Scholar Li Y H. Theory and Technology of Laser Shock Processing[M]. Beijing: Science Press, 2013. Google Scholar
[7]	李伟, 李应红, 何卫锋, 等.激光冲击强化技术的发展和应用[J].激光与光电子学进展, 2008, 45(12): 15-19. Google Scholar Li W, Li Y H, He W F, et al. Development and application of Laser Shock Processing[J]. Laser & Optoelectronics Progress, 2008, 45(12): 15-19. Google Scholar
[8]	陆建, 倪晓武, 贺安之.激光与材料相互作用物理学[M].北京:机械工业出版社, 1996. Google Scholar Lu J, Ni X W, He A Z. Laser and Material Interaction Physics[M]. Beijing: China Machine Press, 1996. Google Scholar
[9]	Nalla R K, Altenberger I, Noster U, et al. On the influence of mechanical surface treatments—deep rolling and laser shock peening—on the fatigue behavior of Ti-6Al-4V at ambient and elevated temperatures[J]. Materials Science and Engineering: A, 2003, 355(1-2): 216-230. doi: 10.1016/S0921-5093(03)00069-8 CrossRef Google Scholar
[10]	Pirri A N. Analytic solutions for laser-supported combustion wave ignition above surfaces[J]. AIAA Journal, 1977, 15(1): 83-91. doi: 10.2514/3.60605 CrossRef Google Scholar
[11]	邹世坤.激光冲击处理技术的最新发展[J].新技术新工艺, 2005(4): 44-46. Google Scholar Zou S K. The latest development of laser shock processing[J]. New Technology & New Process, 2005(44): 44-46. Google Scholar
[12]	Fabbro R, Peyre P, Berthe L, et al. Physics and applications of laser-shock processing[J]. Journal of Laser Applications, 1998, 10(6): 265-279. doi: 10.2351/1.521861 CrossRef Google Scholar
[13]	毕凤琴, 张春成, 李红翠, 等.激光冲击强化技术的发展及应用[J].兵器材料科学与工程, 2010, 33(1): 101-104. Google Scholar Bi F Q, Zhang C C, Li H C, et al. Development and application of laser shock processing[J]. Ordnance Material Science and Engineering, 2010, 33(1): 101-104. Google Scholar
[14]	肖爱民, 杨继昌, 张永康.激光冲击强化原理及应用概述[J].电加工与模具, 2000(6): 7-10. Google Scholar Xiao A M, Yang J C, Zhang Y K. Physical processes of Laser Shock processing and examples of application[J]. Electromachining & Mould, 2000(6): 7-10. Google Scholar
[15]	张宏, 邓琦林, 唐亚新, 等.激光冲击强化技术及其进展[J].航空工艺技术, 1997(1): 19-21. Google Scholar Zhang H, Deng Q L, Tang Y X, et al. Laser shock processing and its progress[J]. Aeronautical Manufacturing Technology, 1997(1): 19-21. Google Scholar
[16]	丁阳喜, 周立志.激光表面处理技术的现状及发展[J].热加工工艺, 2007, 36(6): 69-72. Google Scholar Ding Y X, Zhou L Z. Status and development of laser surface treating[J]. Metal Hotworking Technology, 2007, 36(6): 69-72. Google Scholar
[17]	Montross C S, Wei T, Ye L, et al. Laser shock processing and its effects on microstructure and properties of metal alloys: a review[J]. International Journal of Fatigue, 2002, 24(10): 1021-1036. doi: 10.1016/S0142-1123(02)00022-1 CrossRef Google Scholar
[18]	Askar'yan G A, Moroz E M. Pressure on evaporation of matter in a radiation beam[J]. Soviet Journal of Experimental and Theoretical Physics, 1963, 16: 1638-1639. Google Scholar
[19]	胡太友, 乔红超, 赵吉宾, 等.激光冲击强化设备的开发[J].光电工程, 2017, 44(7): 732-737. Google Scholar Hu T Y, Qiao H C, Zhao J B, et al. Development of laser shock peening equipment[J]. Opto-Electronic Engineering, 2017, 44(7): 732-737. Google Scholar
[20]	Fairand B P, Wilcox B A, Gallagher W J, et al. Laser shock-induced microstructural and mechanical property changes in 7075 aluminum[J]. Journal of Applied Physics, 1972, 43(9): 3893-3895. doi: 10.1063/1.1661837 CrossRef Google Scholar
[21]	Fairand B P, Clauer A H. Laser generation of high‐amplitude stress waves in materials[J]. Journal of Applied Physics, 1979, 50(3): 1497-1502. doi: 10.1063/1.326137 CrossRef Google Scholar
[22]	高玉魁, 蒋聪盈.激光冲击强化研究现状与展望[J].航空制造技术, 2016(4): 16-20. Google Scholar Gao Y K, Jiang C Y. Review and prospect on laser shock peening[J]. Aeronautical Manufacturing Technology, 2016(4): 16-20. Google Scholar
[23]	Clauer A H, Fairand B P, Wilcox B A. Pulsed laser induced deformation in an Fe-3 Wt Pct Si alloy[J]. Metallurgical Transactions A, 1977, 8(1): 119-125. doi: 10.1007/BF02677273 CrossRef Google Scholar
[24]	Universal Technology Corporation. High Cycle Fatigue (HCF) science and technology program 1997 annual report[R]. 1998. Google Scholar
[25]	Universal Technology Corporation. High cycle fatigue science and technology program 1999 annual report[R]. Dayton, Oh: Universal Technology Corporation: Universal Technology Corporation, 2000. Google Scholar
[26]	Universal Technology Corporation. High Cycle Fatigue (HCF) science and technology program 2000 annual report[R]. Dayton, Oh: Universal Technology Corporation, 2000. Google Scholar
[27]	Universal Technology Corporation. High Cycle Fatigue (HCF) science and technology program, 2001 annual report[R]. Dayton, Oh: Universal Technology Corporation, 2002. Google Scholar
[28]	Universal Technology Corporation. High Cycle Fatigue (HCF) Science and Technology Program 2002 Annual Report[R]. Dayton, Oh: Universal Technology Corporation, 2003. Google Scholar
[29]	Bartsch T M. High Cycle Fatigue (HCF) science and technology program[M]//Nuclear Data in Science and Technology, International Atomic Energy Agency, 2002: 607-614. Google Scholar
[30]	Peyre P, Fabbro R, Berthe L, et al. Laser shock processing of materials, physical processes involved and examples of applications[J]. Journal of Laser Applications, 1996, 8(3): 135-141. doi: 10.2351/1.4745414 CrossRef Google Scholar
[31]	Zhang H, Yu C Y. Laser shock processing of 2024-T62 aluminum alloy[J]. Materials Science and Engineering: A, 1998, 257(2): 322-327. doi: 10.1016/S0921-5093(98)00793-X CrossRef Google Scholar
[32]	Ruschau J J, John R, Thompson S R, et al. Fatigue crack growth rate characteristics of laser shock peened Ti-6Al-4V[J]. Journal of Engineering Materials and Technology, 1999, 121(3): 321-329. doi: 10.1115/1.2812381 CrossRef Google Scholar
[33]	Prevéy P S. The effect of cold work on the thermal stability of residual compression in surface enhanced IN718[C]// Proceedings of the 20th ASM Materials Solutions Conference & Exposition, 2000. Google Scholar
[34]	See D W, Dulaney J L, Clauer A H, et al. The air force manufacturing technology laser peening initiative[J]. Surface Engineering, 2002, 18(1): 32-36. doi: 10.1179/026708401225001264 CrossRef Google Scholar
[35]	Sano Y, Mukai N, Okazaki K, et al. Residual stress improvement in metal surface by underwater laser irradiation[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 1997, 121(1-4): 432-436. doi: 10.1016/S0168-583X(96)00551-4 CrossRef Google Scholar
[36]	乔红超, 赵吉宾, 陆莹.激光诱导冲击波应用技术研究现状[J].表面技术, 2016, 45(1): 1-6, 48. Google Scholar Qiao H C, Zhao J B, Lu Y. Current status of laser-induced shock wave application technology[J]. Surface Technology, 2006, 45(1): 1-6, 48. Google Scholar
[37]	Hashmi S, Batalha G F, Van Tyne C J, et al. Comprehensive Materials Processing[M]. Oxford: Elsevier, 2014. Google Scholar
[38]	苏纯, 周建忠, 孟宪凯, 等.温度辅助的激光冲击技术研究进展[J].表面技术, 2016, 45(10): 121-128. Google Scholar Su C, Zhou J Z, Meng X K, et al. Research progress of temperature-assisted laser shock technology[J]. Surface Technology, 2006, 45(10): 121-128. Google Scholar
[39]	Liao Y L, Ye C, Kim B J, et al. Nucleation of highly dense nanoscale precipitates based on warm laser shock peening[J]. Journal of Applied Physics, 2010, 108(6): 063518. doi: 10.1063/1.3481858 CrossRef Google Scholar
[40]	Ye C, Liao Y L, Cheng G J. Warm laser shock peening driven nanostructures and their effects on fatigue performance in aluminum alloy 6160[J]. Advanced Engineering Materials, 2010, 12(4): 291-297. Google Scholar
[41]	Lin D, Suslov S, Ye C, et al. Laser assisted embedding of nanoparticles into metallic materials[J]. Applied Surface Science, 2012, 258(7): 2289-2296. doi: 10.1016/j.apsusc.2011.09.132 CrossRef Google Scholar
[42]	Liao Y L, Suslov S, Ye C, et al. The mechanisms of thermal engineered laser shock peening for enhanced fatigue performance[J]. Acta Materialia, 2012, 60(13-14): 4997-5009. doi: 10.1016/j.actamat.2012.06.024 CrossRef Google Scholar
[43]	Kalentics N, Boillat E, Peyre P, et al. Tailoring residual stress profile of Selective Laser Melted parts by Laser Shock Peening[J]. Additive Manufacturing, 2017, 16: 90-97. doi: 10.1016/j.addma.2017.05.008 CrossRef Google Scholar
[44]	刘志东, 杨怡生, 余承业.激光冲击强化改善金属疲劳特性的研究[J].航空工艺技术, 1992(5): 8-12. Google Scholar Liu Z D, Yang Y S, Yu C Y. Using laser shock processing to improve metal fatigue property[J]. Aeronautical Manufacturing Technology, 1992(5): 8-12. Google Scholar
[45]	高建民.我国首台激光冲击强化装置问世[J].高技术通讯, 1996(9): 32. Google Scholar Gao J M. Chinese first laser shock peening equipment is published[J]. High Technology Letters, 1996(6): 32. Google Scholar
[46]	佚名.我国第一条激光冲击强化生产线建成[J].军民两用技术与产品, 2009(1): 29. Google Scholar Anonymous. Chinese first laser shock peening production line is established[J]. Dual Use Technology & Products, 2009(1): 29. Google Scholar
[47]	乔红超, 高宇, 赵吉宾, 等.激光冲击强化技术的研究进展[J].中国有色金属学报, 2015, 25(7): 1744-1755. Google Scholar Qiao H C, Gao Y, Zhao J B, et al. Research process of laser peening technology[J]. The Chinese Journal of Nonferrous Metals, 2015, 25(7): 1744-1755. Google Scholar
[48]	中科院宁波材料技术与工程研究所.新一代激光冲击强化技术研究获得突破[J].表面工程与再制造, 2017, 17(1): 53. Google Scholar Ningbo Institute of Material Technology and Engineering, CAS. A new generation of laser shock peening technology get a breakthrough[J]. Surface Engineering & Remanufacturing, 2017, 17(1): 53. Google Scholar

Overview

Overview

Overview: The fatigue properties of metal components are related to their surface integrity closely. In general, the components’ fatigue fracture, especially the high-cycle fatigue fracture is often due to the surface cracks, and the gradual expansion of the crack may leads to the overall destruction. In order to improve the structural reliability and extend the fatigue life without changing the properties of the matrix material, the surface strengthening technology has got more and more research and application internationally. Common surface strengthening techniques include shot peening, surface rolling, forging and extrusion, etc. Shot peening is a surface technology that uses the high-speed projectile to hit the material surface, which can produce Strain hardening layer and cause residual compressive stress in the surface. The compressive stress can cancel part of the working load (tensile stress), thereby enhancing the fatigue strength of the parts. Surface rolling can apply a certain amount of pressure to the surface of material by the rolling tools, and the local slight plastic deformation would occur in the surface of material, and improve the surface roughness and uniform the stress field distribution. Certainly, the technology of forging and the extrusion can introduce a certain amount of pressure in the surface of materials, and it can improve the mechanical properties and service life of materials too. With the development of high-end equipment such as aerospace, weapons, nuclear energy and transportation, the surface requirements of parts are becoming higher and higher. The traditional strengthening technique such as shot peening and surface rolling will difficult to meet the production requirements of high-performance equipment gradually. But the laser shock processing can solve these problems well. Laser shock processing is a new surface strengthening technology that can improve the fatigue life of materials by using laser-induced plasma shock waves. It has the advantages of significant strengthening effect, strong controllability and good adaptability. Laser shock processing plays an important role in improving the structural reliability, the fatigue strength of parts and the service life of materials. In recent years, laser shock processing has received widespread attention and developed rapidly. This paper briefly introduces the basic principle, characteristics and application fields of laser shock processing, and summarizes the development and research results of laser shock processing. In view of the current situation of laser shock processing at home and abroad, some problems of the technology that need to be solved now are put forward. Finally, the application prospect of laser shock processing is forecasted.